KR20090042266A - Subscriber unit for a cellular communication system - Google Patents

Abstract

A subscriber unit, for a cellular communication system, is arranged to store data representing a message to be transmitted together with data representing specified conditions associated with the transmission of the message. The subscriber unit responds to the specified conditions being met by transmitting the message. The specified conditions may be dictated by the network or by the user of the subscriber unit or by a combination of the two, and include time, date, location, and network loading.

Description

Subscriber unit for cellular communication system {SUBSCRIBER UNIT FOR A CELLULAR COMMUNICATION SYSTEM}

The present invention relates to a subscriber unit for a cellular communication system. The subscriber unit may be operable to perform data transmission based on defined conditions.

For a long time cellular communication systems and other communication networks (hereinafter simply referred to as "networks") have provided subscribers with so-called short message service (SMS) services. SMS messages are text based and have become increasingly popular with young users in many countries and regions. As networks move from formed second generation (2G) technology to next generation technology (3G), more networks will further provide so-called multimedia message service (MMS) services.

As the names suggest, MMS messages include multimedia messages with text, audio files, graphical animations, and the like. Examples of such messages in a 2G system include emails, web pages and still images. Next-generation 3G systems have the ability to support more media-rich messages and applications, including the transmission and reception of multimedia data representing multi-user games and video, sound clips, video fragments, and the like.

As with text-based SMS services, users can now create their own MMS messages and send and receive those MMS messages from their contacts. In addition, additional services may be used that allow MMS messages with abundant multimedia content to be received from commercial content creators.

While similar to these applications have been used on PCs for a long time, their transfer to a wireless mobile environment presents new challenges and opportunities. The movement of wireless networks with packet switching creates possibly virtual connections, creating the possibility of so-called "bandwidth-on-demand". Packet switching can be used to ensure that a user is always connected to the network.

Although this increase in messaging capabilities brings many advantages, it will also result in the need for greater control over the transmission of SMS and MMS messages by the user, the network, or both. From the user's point of view, cost is often a concern, and sending high data-volume messages such as web pages, images, and video has the potential to quickly incur high charges by the network. From a network point of view, the problem is a kind of loading. During peak times, the bursty nature of high data-volume messages can cause localized network loading problems, which can thus affect the quality of service to be provided to users. This will increase as more users move to multimedia-rich packet based services.

It is an object of the present invention to solve or at least reduce the above and related problems. To this end, the present invention aims to provide data transmission on the basis of prescribed conditions. That is, the purpose is to provide automatic activation of SMS, MMS or other data transmission, in particular based on any one or more of a data stamp, time stamp, geographical location, or network loading. Thus, the above defined conditions may be indicated by the network or by the user of the subscriber unit or by a combination of the two.

In accordance with an aspect of the present invention, there is provided a subscriber unit for a cellular communication system, which stores data representing the message to be transmitted with data representing prescribed conditions associated with the transmission of the message, By sending the message it is arranged to comply with the above defined conditions being met.

According to another aspect of the present invention, there is provided a method of preparing a message for transmission in a cellular communication system, wherein data indicative of a message to be transmitted is accompanied by data indicative of prescribed conditions associated with the transmission of the message. Stored in the unit, and the message is transmitted when the specified condition is met.

According to another aspect of the present invention, there is provided a method for transmitting a message in a cellular network, the method comprising: generating message data indicative of a message to be transmitted; Generating condition data defining one or more defined conditions associated with transmission of a message to be represented by said message data; Storing the condition data; Determining when the one or more prescribed conditions are met; And transmitting the message represented by the message data when the one or more prescribed conditions are met.

The invention also provides an apparatus for transmitting a message in a cellular network, the apparatus comprising: means for generating message data indicative of a message to be transmitted; Means for storing the message data; Means for generating condition data defining one or more defined conditions associated with transmission of a message to be represented by said message data; Means for storing the condition data; Means for determining when the one or more prescribed conditions are met; And means for transmitting a message represented by the message data when the one or more prescribed conditions are met.

The above and further features of the present invention are specifically described in the appended claims, the advantages of which will become more apparent from the following description of exemplary embodiments of the invention provided with reference to the accompanying drawings.

1 shows a schematic system diagram of a subscriber unit implementing the present invention.

2 graphically depicts a loading pattern over a typical time of a cellular network.

3 is a flow chart of the decisions made by the network and subscriber units and the interaction between them during uploading of data according to the network.

4 schematically shows the cells of a cellular network.

Referring now to FIG. 1 of the accompanying drawings, there is shown a schematic system diagram of a subscriber unit 10 implementing the present invention. The term "subscriber unit" will be used herein to refer to an apparatus within that cellular system that interfaces with users of the cellular system. The device may be a mobile or stationary device and need not be a single unit. In general, the "subscriber unit" will be a mobile phone or cell phone that is popularly known for use in cellular networks. However, the present invention may be implemented in a device located in a fixed location and / or in a device including some units that perform the functions and operations described below together.

Subscriber unit 10 includes an antenna 12 for receiving signals from a cellular network (not shown in FIG. 1) and also for transmitting signals to the cellular network. For the purposes of this description, the subscriber unit 10 is shown divided into two paths 16, 18 by a dashed line 14. The path 16 includes functional units that together process the location-related information received by the subscriber unit 10. The path 18 includes functional units that together handle the transmission and reception of voice data and user data. This division is conceptual in nature and does not need to be implemented in a real device.

Dividing the paths 16 and 18 into functional units is merely an idea provided to facilitate understanding of the operation of the two paths. In practice, the paths do not have to be divided into separate functional units as shown. The functional units can be combined or further divided, the choice being only a matter of design by those skilled in the art.

The position data processing path 16 includes a position data receiving / decoder unit 20 coupled to receive position signals from the antenna 12. The receiver / decoder unit 20 may be constructed from a variety of different sources, including a network (not shown) in which the subscriber unit operates in use, a global positioning system (GPS), or even a Galileo system intended for implementation in the near future. It may be configured to receive the location information. Such position-locating techniques are well known. Subscriber unit 10 uses data obtained through a GPS system using standard techniques familiar to those skilled in the art. The acquisition of GPS system and GPS data will therefore not be described in detail herein.

The position signals received from the antenna 12 are decoded by the receiver / decoder unit 20 before being transmitted to the position data processing unit 22 connected to the receiver / decoder unit 20. The position data processing unit 22 extracts the position-related information from the decoded signals, and typically stores the extracted position-related information in the position database 24 as coordinate information.

In addition to the data from the location data processing path 16, the location database 24 stores data defining coordinates of predetermined and / or user-selected locations. The data in location database 24 may be preloaded into storage or may be entered by a user. In addition to the data defining the coordinates of the given locations, the data in the location database 24 includes data defining the identifiers assigned by the user, namely names tags such as "home", "work", "office", "airport" and the like. . The user-selected data may be entered into the location database 24 when the subscriber unit 10 is actually at that location. These user-defined names, each of which is associated with a set of GPS coordinates, form a database in subscriber unit 10.

The term database is used herein simply as a label for convenience. The database can be as simple as a lookup table or as complex as a relational database depending on the level of sophistication at which the subscriber unit is intended to operate. In most applications, the database will be very similar to an address book or phone book except for storing place information. Thus, a database may also be called a "place book".

Further description of the operations and functions performed by the location data processing path 16 is provided below. These operations and functions depend on the operations and functions of the data transmit and receive path 18 to which the present description will now refer.

The data transmission and reception path 18 includes a voice / user data transceiver 26 coupled to receive signals representing voice and / or data from the antenna 12. The transceiver 26 is configured in use to receive signals from a network (not shown) in which it operates. The transceiver 26 demodulates the received signals prior to passing them to the decoding unit 28 to which they are connected. The decoding unit 28 decodes the demodulated signals, that is, extracts data from the demodulated signals, and also passes the extracted data to the data processing and control unit 30. The data processing and control unit 30 examines the data it receives from the decoding unit 28 and determines what to do with that data.

If the data simply represents a voice signal, the data processing unit 30 may output the data directly to the user interface driver 32. The user interface driver 32 is connected to the loudspeaker 34, the microphone 36, the display 38 and the keyboard 40, thus actually providing various connections to the user. In the case of a voice signal, the user interface 32 converts the voice data into an analog signal and outputs the analog signal to drive the loudspeaker 36. Thus, the audio signal is reproduced as an audio output.

The data received may indicate control signals to use in controlling the operation of the subscriber unit. These control signals control the transmission and reception of RF signals between the subscriber unit and the network (not shown). The control signals and the manner in which the subscriber unit responds to the control signals are controlled by various established communication standards. The invention is not specified by any particular standard. For brevity, these control signals will not be described later herein.

User data in the received signal follows the user data path 18 through the transceiver 26, the decoding unit 28, and the data processing and control unit 30. The user data may be, for example, a simple SMS message such as a text message from another user (not shown) or billing information from the network. User data may be data representing an image (ie, a jpeg file), music (ie, mp3 file), or executable application (ie, Java applet).

The data processing and control unit 30 processes the received user data, responds to the user data and / or stores the user data in the message memory and / or the user information database 44. These two units 42, 44 are shown in separate units simply for ease of explanation. In practice, the units 42, 44 may be combined with each other and, if desired, with the location database 24 in a single unit.

Depending on the nature of the data, the data processing and control unit 30 may also generate an audio signal for output through the loudspeaker 34 when the user is audibly informed that the data has been received. With or instead of this, the control unit 30 can generate signals for output to the display 38 when visually notifying the user. The display may also include instructions for restoring data, typically by user manipulation of the keyboard 40. This type of user interaction is a simple routine design problem and therefore does not need to be described in more detail herein.

Audio signals sensed by the microphone 36 (ie, typically speech) are converted into speech data by the user interface driver 32. Thus, the user interface driver functions as a vocoder that converts voice signals into digital data in a format appropriate for transmission. Communication systems are particularly defined by different standards that specify how a vocoder converts voice signals into data for transmission. The shape of the vocoder is not closely related to the present invention, and the present invention can be equally applied to various standards. Thus, the vocoding function performed by the user interface driver need not be described in further detail herein.

The generation of SMS and MMS messages is controlled by user manipulation of the keyboard 40 and interaction with the user via the display 38. This type of user interaction is a simple routine design problem and therefore does not need to be described in more detail herein. The final SMS / MMS message is stored as data in the message memory 42. The message data is kept in the message memory for an appropriate time period until user-defined conditions are met.

After editing, the subscriber unit 10 will provide the following options menu for transmission:

(1) sending a message after a time and date that may be set to remind the user or a third party to do something, such as 17:00 today;

(2) if, for example, a message is generated in an area where the service is not available, transmission until the service is available; And

(3) Proximity of subscriber unit 10 to a point within 10 miles of a "home" as defined, for example, in a place book by the user.

When user-specific conditions are met, data indicative of an SMS / MMS message is transferred from the memory 42 via the control unit 30 to the encoder 46 for transmission by the transceiver 26. The encoder 46, together with the data processing and control unit 30, is provided for encoding the SMS / MMS data in a form suitable for transmission. The form of data generated by the control unit 30 and the encoder 46 is not closely related to the present invention. In addition, the present invention can be equally applied to various standards, and thus the form of data generated by the control unit 30 and the encoder 46 will not be described in more detail herein.

Subscriber unit 10 may operate under user control to delay the transmission of a user-generated message (SMS or MMS) until various conditions are met or one or more user-specific actions have occurred. Thus, the subscriber unit 10 is configured to allow the user to store the SMS / MMS message with data identifying the conditions to be met before the SMS / MMS message is sent. The subscriber unit 10 uses the above trigger conditions to determine when to send an SMS / MMS. Once the trigger condition is met, the condition is changed to transmit now (or to send as soon as possible). For example, if a message has a trigger condition "Send after 17:00 today", once at 17:00, the condition is met and changes to "Send now".

The "time and date" option may be useful in many situations. For example, a businessman may write down customer visits (or set appointments) that he should make during today and until today, and these summaries may be sent to his office for actions to be performed in his office. It may also be used to take advantage of any off-peak tariffs. In this case, by simply setting the features on the subscriber unit 10 menu, the data will be automatically delivered during off peak hours or night time without any additional user intervention.

The "Send Now" option will result in one of two responses. First, if subscriber unit 10 is in service, the message will be sent immediately. Second, if the subscriber unit 10 is not in use, the message will be sent as soon as the network service is reset without requiring user intervention. This is to inform, for example, that the user has arrived at a third party who has agreed to meet the user at the airport and also suggests a place to meet the user.

The "Proximity" option may be useful to let a third party know when the user is close to home (eg, while driving, etc.), or may be used to inform colleagues of when the user is likely to arrive at work, etc. have.

The above options may also be combined such that a message may be sent when both time and date conditions and proximity conditions, such as after 17 o'clock today and within 10 km of “home”, are met.

2 of the accompanying drawings is a graph illustrating a typical loading pattern of a cellular network. As can be seen from the graph of FIG. 2, network usage is very small during night hours and high during business hours. With current voice services, higher rates are applied during peak periods, and users incur lower costs during off-peak periods. Thus, network loading can be simply time dependent. For example, the network may set a peak time between 7 am and 7 pm. Calls made during such time periods will be charged a premium, while calls made at other times will be charged off-peak.

It is difficult for network operators to determine rates and generalize how individual operators handle fees for data transmission. Nevertheless, in order to match the historical rates for voice connections, at least some operators will charge at different rates at different times for data transmission. Costs are often of interest from the user's point of view, and sending high data-volume messages such as web pages, images, and video has the potential to incur high rates instantly by the network.

As a result, the user of the MMS application may wish to delay the transmission of the selected MMS message until the off-peak period to take advantage of low rates. Similarly, a user may want to delay receiving data from the network (file downloading from a remote server) until various conditions are met or one or more user-specific actions are issued.

Thus, the subscriber unit 10 is configured to allow the user to define that the transmission of the message is delayed until one or more user-specific conditions are met. These conditions include, but are not limited to, date, time, network loading, and geographic location. The first two conditions are relatively simple. Through user interaction with the display 38 and the keyboard 40, data defining the day and / or time is entered and stored in the information database 44.

The data processing and control unit 30 moves these messages from the message memory 42 to the encoder 46 for transmission over the network via the transceiver 26 and the antenna 12 so that these conditions are met. Are arranged to comply. In the simplest case, the control unit 30 monitors the current time (based on information received by the control unit 30 from the network, or based on internally generated data, or both). It will also monitor when its current time matches the time condition stored in the user information database 44. Whether the message is removed from the memory 42 once it has been sent is a matter of design choice and depends in particular on the capacity of the memory, the physical size of the subscriber unit, and the cost.

More sophisticated applications are likely to be required by the network and / or users. Thus, sometimes there will be other options to place subscriber unit 10 to receive network-loading information from the network. The transmission of this information, although small on the network, creates additional load. Thus, the regularity with which network-loading information is sent to subscriber unit 10 is a matter of design choice to balance the allocation of network services to the quality of service provided to the user.

In the foregoing description, many “intelligences” (ie, data processing, decision making, etc.) are placed in subscriber unit 10. There may be times when some intelligence may be preferably deployed with the network. One such situation would relate to message transmissions based on network loading. For example, there may be a need intended by the network to reduce the transmission of data for data-centric applications during peak times to maximize network capacity for voice traffic.

Although the network may set the "peak" times between 7 am and 7 pm, nevertheless there will be short periods of the day where the load on the network is below the selected level, eg short periods with less than average loading. . These short periods of time can be used by the network to upload time-dependent SMS / MMS messages from subscriber unit 10.

3 of the accompanying drawings is a flow chart 50 of the determination by interaction between the network and the subscriber unit during network-dependent uploading of data representing SMS / MMS messages. In stage 52, when a time-dependent message is generated, the subscriber unit 10 may network the status message to identify the size of the message, the desired transmission time or other conditions, and the intended destination for the SMS / MMS message. To transmit. In stage 54, the network responds to the status message by recording the size of the SMS / MMS message and the conditions attached to its transmission.

Because the network knows which cell each subscriber unit 10 belongs to and also how much data each subscriber unit should transmit, the network can calculate the total amount of data remaining for each cell. have. In this way, the network can determine when sufficient resources are available, thereby allowing data to be transferred from the subscriber unit (s) to the network.

As shown by stage 56 of FIG. 3, the network urges subscriber unit 10 to upload a message (or portions of the message) during periods of activity less than average activity. The upload is triggered (at subscriber unit 10) using a protocol message sent over a control channel in the network. The protocol message will simply instruct subscriber unit 10 to proceed with data transfer because network resources (ie capacity) are currently available. The characteristics of the control channels are determined by the standards applicable to the network. Depending on the standards involved in the implementation, either the paging channel, broadcast channel or other control channels can be used to carry the protocol message.

Depending on the amount of resources available, the network may decide to upload data in other ways. For example, the network may decide to upload in the following ways:

(1) uploading from a particular subscriber unit, which may have a large amount of data or different types of data pending, since the status of all subscriber units 10 is notified to the network;

(2) uploading from any subscriber unit assigned to a particular group of channels on the cell;

(3) uploading from any subscriber unit on a particular sector of the cell;

(4) uploading from any subscriber unit on a particular cell; or

(5) Uploading from any subscriber unit on cells of a particular group.

(6) Uploading based on the type of subscriber.

The message is queued at a message server on a network (not shown) with data defining the delivery time for subsequent forward transmission to its intended destination. Once the upload is complete, as shown in stage 58 of FIG. 3, the network sends an upload acknowledgment signal to the subscriber unit. The subscriber unit responds to the acknowledgment signal by marking the SMS / MMS message when sending and clearing (if necessary) the SMS / MMS message from its memory 42 (see FIG. 1).

When the conditions associated with the SMS / MMS message are true, the network transmits the queued message to the intended recipient, as shown in stage 60 of FIG. Thereafter, as shown in stage 62, the message is cleared from that server's queue for free space on the server for other messages.

From the network point of view, this solution has the advantage of optimizing the use of the network for a day while at the same time preventing unnecessary loading during periods of above average activity. From the user's point of view, this solution offers the advantage of sending data at off-peak rates.

The solution ensures that the message is uploaded unexpectedly quickly, thereby ensuring that the message is delivered at the desired time. It also solves some of the problems associated with sending messages when the service is interrupted. In general, in order to send and receive SMS / MMS messages, the subscriber unit 10 must be busy. That is, the subscriber unit 10 must be synchronized to the serving cell on the mobile network in order for the message generated by the mobile user to be transmitted immediately. Moving intelligence to the network will reduce the likelihood that message "calls" will be interrupted due to service interruptions.

The "proximity" condition requires that the geographical location of the subscriber unit 10 be informed. There are several ways to do this. 4 of the accompanying drawings schematically shows a cellular network 70 in which a subscriber unit 10 is located.

The network 70 includes a plurality of cells 71, 72, 73, 74, 75 covering the service area. For convenience, the cells 71-75 are shown in interlocking hexagons. This is an ideal city, and in fact the shape of the cells will be determined by many environmental factors, including relative signal strength, terrain, and even time of day. Each of the cells is served by respective base stations 81, 82, 83, 84, 85 forming a network with other devices (not shown).

At its simplest level, the network knows at any time the cell in which the subscriber unit 10 is located. This acknowledgment may be used to provide an approximate location indication to the subscriber unit 10. This solution will not be very accurate, and the answer will depend on the size and separation of cells in the network. Nevertheless, it may be sufficient to inform whether the subscriber unit 10 is located in a given village or town, which may be sufficient for any proximity conditions.

At a more sophisticated level, mobile stations may one day collect location information from a global positioning system (GPS) or even a Galileo system when implemented. The GPS (or similar) receiver of the subscriber unit 10 requires good reception of the GPS signal and a lot of processing power to calculate the location. An alternative solution is a so-called Assisted GPS (AGPS) system, which includes an assistant server that takes over some of the calculations the network needs to determine the location of the subscriber unit 10.

Depending on the method used, the "intelligence" for proximity-dependent messages may be placed in the subscriber unit (as shown in FIG. 1), or may be placed in the network (as already described with respect to other conditional messages). As shown), it can be placed in both the subscriber unit and the network. In the following description it is assumed that the intelligence is in the subscriber unit 10 as shown in FIG. 1 of the accompanying drawings.

The location database 24 (see FIG. 1) in the subscriber unit 10 includes a list of pre-entered places known to the user (or important to the user) (determined by the GPS coordinates of the places). There are many different ways of inputting such data into location-determining devices, such as GSP receivers, so this aspect does not need to be described in detail herein any further.

When a user generates a location-dependent message (ie, a message whose transmission depends on whether the subscriber is located within a specific location or within a defined range), the data is stored in the subscriber unit. The data processing and control unit 30 causes the message to be stored in the message memory 42 and the information indicative of the location conditions is stored in the user information database 44. Thereafter, the data processing and control unit 30 compares the information stored in the user information database 44 with the position data (current coordinates) stored in the position database 24. When the coordinates are met, the data processing and control unit 30 causes the message to be sent in the manner already described above.

Thus, although the invention has been described with reference to a preferred embodiment, that embodiment is merely exemplary, and modifications and variations are to those skilled in the art without departing from the spirit and scope of the invention and its equivalents as described in the appended claims. You will know that it will be done by you.

Claims (48)

A subscriber unit for a cellular communication system, The subscriber unit is arranged to store data indicative of a message to be transmitted together with data indicative of prescribed conditions associated with the transmission of the message to be transmitted, and to respond to the prescribed conditions being met by transmitting the message to be transmitted. , Subscriber unit. The method of claim 1, The conditions stipulated above include time, The subscriber unit is arranged to monitor the time of day and send a message at a prescribed time, Subscriber unit. The method of claim 1, The conditions stipulated above include the date, The subscriber unit is arranged to monitor a date and to send a message on a prescribed date, Subscriber unit. The method of claim 1, The conditions defined above include a location, The subscriber unit is arranged to monitor its location and to send a message at a defined location, Subscriber unit. The method of claim 1, wherein the defined conditions include any two or more of the conditions defined in claims 2 to 4. Subscriber unit. The method according to any one of claims 1 to 5, A receiver for receiving signals from a cellular network; And And a processor for decoding the received signals to extract data from the received signals, responsive to the data when the data represents control information, and storing the data when the data represents a message. , Subscriber unit. The method according to any one of claims 1 to 6, In response to the processor, further comprising a user interface for outputting an indication of the arrival of a message, Subscriber unit. 8. The system of claim 7, wherein the processor generates a message for transmission in response to a user manipulation of the user interface. Subscriber unit. The apparatus of claim 7 or 8, wherein the user interface comprises a keypad and a display for displaying messages. Subscriber unit. The method of claim 8, A message storage unit for storing data representing messages generated for transmission; A message data storage for storing data representing prescribed conditions associated with the transmission of the message; And And a transmitter for transmitting the messages stored in the message storage unit. The processor is operable to transfer data from the message store to the transmitter for transmission, Subscriber unit. 11. The system of any of claims 1 to 10, further comprising a location processor for processing location signals received by a receiver to determine the geographical location of the subscriber unit. Subscriber unit. 12. The apparatus of claim 11, further comprising a separate location data receiver for receiving location data, Subscriber unit. 13. The system of claim 12, further comprising a location database in which location data indicative of the geographic location of the subscriber unit is stored, Subscriber unit. The method of claim 13, wherein the data indicative of the defined conditions is compared with data in the location database to determine whether to send a message. Subscriber unit. The method according to any one of claims 1 to 14, further comprising regulatory means for allowing the conditions to be defined by the user of the subscriber unit. Subscriber unit. 16. The apparatus of any of claims 1-15, further comprising means for complying with the conditions defined by the network. Subscriber unit. A method for preparing a message for transmission in a cellular communication system, the method comprising: In the method, data indicative of a message to be transmitted is stored at the subscriber unit together with data indicative of prescribed conditions associated with the transmission of the message to be transmitted, and the message to be transmitted is transmitted when the prescribed conditions are met, How to prepare a message for transmission. The method of claim 17, The conditions stipulated above include time, The method further comprises monitoring the time of day, and sending a message at a defined time, How to prepare a message for transmission. The method of claim 17, The conditions stipulated above include the date, The method further comprises monitoring a date, and sending a message on a prescribed date, How to prepare a message for transmission. The method of claim 17, The conditions defined above include a location, The method further comprises monitoring a location of a subscriber unit, and sending a message when the subscriber unit is at a defined location, How to prepare a message for transmission. The method of claim 17, wherein the defined conditions include any two or more of the conditions defined in claims 18-20. How to prepare a message for transmission. The method according to any one of claims 17 to 21, Receiving signals from a cellular network; Decoding the received signals to extract data from the received signals; Responding to the data when the data represents control information; And Storing the data when the data indicates a message, How to prepare a message for transmission. 23. The method of any one of claims 17 to 22, further comprising outputting an indication of the arrival of the message, How to prepare a message for transmission. The method according to any one of claims 17 to 23, wherein Storing data indicative of messages generated for transmission; Storing data indicative of prescribed conditions associated with the transmission of the message; And Further comprising sending the stored messages, How to prepare a message for transmission. 25. The method of any one of claims 17 to 24, further comprising processing received location signals to determine a geographical location of the subscriber unit. How to prepare a message for transmission. 27. The method of claim 25, further comprising storing location data indicative of the geographic location of the subscriber unit. How to prepare a message for transmission. 27. The method of claim 26, further comprising comparing data representing the defined conditions with stored location data to determine whether to transmit a message. How to prepare a message for transmission. 28. The method of any one of claims 17 to 27, further comprising allowing a user of a subscriber unit to define conditions. How to prepare a message for transmission. 29. The method of any one of claims 17 to 28, further comprising enabling the network to define conditions. How to prepare a message for transmission. A method of transmitting a message in a cellular network, Generating message data indicative of the message to be transmitted; Storing the message data; Generating condition data defining one or more prescribed conditions associated with transmission of a message represented by said message data; Storing the condition data; Determining when the one or more prescribed conditions are met; And Sending a message represented by the message data when the one or more prescribed conditions are met, How to send a message. The method of claim 30, The conditions stipulated above include time, The method further comprises monitoring the time of day, and sending a message at a defined time, How to send a message. The method of claim 31, wherein The time is determined as the time when network loading is low, The method further comprises monitoring loading on the network, How to send a message. 33. The method of claim 32, further comprising sending a message when network loading is low, How to send a message. 31. The method of claim 30, further comprising sending a message during an off-peak period defined by the network. How to send a message. The method of claim 30, The conditions stipulated above include the date, The method further comprises monitoring a date, and sending a message on a prescribed date, How to send a message. The method of claim 30, The conditions defined above include a location, The method further comprises monitoring a location of a subscriber unit, and sending a message when the subscriber unit is at a defined location, How to send a message. 37. The method of any one of claims 30 to 36, further comprising allowing a user of the subscriber unit to define conditions. How to send a message. 38. The method of any one of claims 30 to 37, further comprising enabling the network to define conditions. How to send a message. An apparatus for transmitting messages in a cellular network, the apparatus comprising: Means for generating message data indicative of a message to be transmitted; Means for storing the message data; Means for generating condition data defining one or more prescribed conditions associated with transmission of a message represented by said message data; Means for storing the condition data; Means for determining when the one or more prescribed conditions are met; And Means for transmitting a message represented by said message data when said one or more prescribed conditions are met, Message transmission device. The method of claim 39, The conditions stipulated above include time, The apparatus further comprises means for monitoring the time of day, and means for sending a message at a defined time, Message transmission device. The method of claim 40, The time is determined as the time when network loading is low, The apparatus further includes means for monitoring loading on the network, Message transmission device. 42. The apparatus of claim 41, further comprising means for sending a message when network loading is low. Message transmission device. 42. The apparatus of claim 41, further comprising means for sending a message during an off-peak period determined by the network. Message transmission device. The method of claim 39, The conditions stipulated above include the date, The apparatus further comprises means for monitoring a date, and means for sending a message on a defined date, Message transmission device. The method of claim 39, The conditions defined above include a location, The apparatus further comprises means for monitoring the location of the subscriber unit, and means for sending a message when the subscriber unit is in a defined location, Message transmission device. 46. The method of any one of claims 39 to 45, further comprising regulatory means for allowing conditions to be defined by a user of the subscriber unit. Message transmission device. 47. The apparatus of any one of claims 39 to 46 further comprising means for responding to conditions defined by the network. Message transmission device. A method or apparatus as described herein with reference to the accompanying drawings.

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